Abstract
An approach based on Artificial Neural Networks is proposed in this paper to improve the localisation accuracy of Inertial Navigation Systems (INS)/Global Navigation Satellite System (GNSS) based aided navigation during the absence of GNSS signals. The INS can be used to continuously position autonomous vehicles during GNSS signal losses around urban canyons, bridges, tunnels and trees, however, it suffers from unbounded exponential error drifts cascaded over time during the multiple integrations of the accelerometer and gyroscope measurements to position. More so, the error drift is characterised by a pattern dependent on time. This paper proposes several efficient neural network-based solutions to estimate the error drifts using Recurrent Neural Networks, such as the Input Delay Neural Network (IDNN), Long Short-Term Memory (LSTM), Vanilla Recurrent Neural Network (vRNN), and Gated Recurrent Unit (GRU). In contrast to previous papers published in literature, which focused on travel routes that do not take complex driving scenarios into consideration, this paper investigates the performance of the proposed methods on challenging scenarios, such as hard brake, roundabouts, sharp cornering, successive left and right turns and quick changes in vehicular acceleration across numerous test sequences. The results obtained show that the Neural Network-based approaches are able to provide up to 89.55% improvement on the INS displacement estimation and 93.35% on the INS orientation rate estimation.
Highlights
The safe navigation of autonomous vehicles and robots alike is dependent on fast and accurate positioning solutions
As the Input Delay Neural Network (IDNN) is characterised by a significantly lower number of parameters compared to the Gated Recurrent Unit (GRU), Long Short-Term Memory (LSTM) and Vanilla Recurrent Neural Network (vRNN) whilst providing similar Cumulative Root Squared Error (CRSE) scores across all neural networks (NN) studied and weight connections explored, we adopt it for use in learning the sensor noise in the accelerometer and gyroscope in this study
Network-based approach inspired by the operation the feed-of the feedWe propose a Neural Network-based approach inspired by theof operation back control system to improve the localisation of autonomous vehicles robots alike back control system to improve the localisation of autonomous vehicles and robotsand alike
Summary
The safe navigation of autonomous vehicles and robots alike is dependent on fast and accurate positioning solutions. The evaluation of the performance of positioning algorithms present in most published works may not accurately reflect real-life vehicular driving experience As those complex scenarios present strong challenges for INS tracking, it seems essential for the reliability of the algorithms to be assessed under such scenarios:. Where εbx and εbv are the noise characterising the INS’s displacement and velocity information formulation derived from εba , δbINS, a is the sensors bias in the body frame calculated as a constant parameter from the average reading of a stationary accelerometer ran for 20 min, FIbNS is the corrupted measurement of the accelerometer sensor at time t (sampling time), g. Using the North-East-Down (NED) system, the noise εbx , displacement x bINS , velocity vbINS and acceleration abINS of the vehicle in the body frame within the window t − 1 to t can be transformed into the navigation frame using Rnb as shown in Equations (15)–(19).
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